Introduction to Signals, Passive RC Filters and Opamps

Transcription

1 Introduction to Signals, ive RC Filters and Opamps LB Introduction In this laboratory exercise you design, build and test some simple filter circuits. his is mainly for you to get comfortable with circuit design in the frequency domain, and as a brief introduction/review of filtering. Filters are important blocks in all communication and instrumentation systems. filter is abstractly represented in terms of the transfer function, H(j), as shown in Figure. Filters are often categorized depending on the frequency domain behavior of the transfer function magnitude. Ideal frequency responses for lowpass, highpass, and bandpass filters are shown in Figure 2. (j) Hj ( ) = V out ( j) ( j) V out (j) Figure bstract two-port representation of a filter circuit. I. RC Circuits and Frequency Response Design a passive (no active components; e.g. transistors or opamps) second-order low-pass filter which meets the following specifications (specs): he input impedance of the filter (Z in in Fig. ) should be sufficiently large compared to the signal-source output impedance which is 5Ω. he output impedance of the filter (Z out in Figure 3 with input source grounded) should be sufficiently small compared to the input impedance of the load, which is MΩ and pf. magnitude response that has 3dB signal attenuation at khz and at least 2db signal attenuation at khz. he simplest possible circuit for this filter design is shown in Figure 3.

2 Lab : Introduction to Signals, ive RC Filters and Opamps H(j) High- L H H(j) Low- L H H(j) Band- L H H(j) Notch Filter L H Figure 2 Ideal filter characteristics. FILER SOURCE R R 2 B v out LOD R S Z in Zout R L C L C C 2 Figure 3 second-order RC low pass filter. Design Procedure ssuming that RS<<R, CL<<C2, and the magnitude of Zout, the transfer function for this RC filter can be approximated as: R R 2 C C R C R 2 C R 2 C 2 R R 2 C C 2 V out = (4) s 2 s

3 Lab : Introduction to Signals, ive RC Filters and Opamps here are four design variables and two poles to achieve the required frequency response. he additional constraints come from the input and output impedance specifications. Explain how you selected your circuit values in your lab books and in your lab report. Use your signal generator as the source, and your oscilloscope as the load to measure and plot the magnitude and phase responses of the output from Hz to MHz. Verify that your signal generator and oscilloscope are reasonably close to the actual source and load specifications. Plot your data on graphs in db on a semi-log scale. Include on your graphs the Bode plots you obtain from the transfer function shown in equation (4). In your report comment on your experimental results. How well does the Bode plot approximate the real response? If your design had an output impedance comparable to that of the scope, how would it affect the overall transfer function? Ideally what values would you want for the input and output impedances of your filter? Explain why it is not possible to approach these ideal values for this design. II. Filter Design using Opamps Our filtering capabilities with passive components is quite limited. It is extremely difficult to meet aggressive specs and produce a reasonably high quality filter response. Opamps can be used with R s and C s (and L s) to create superior filters in terms of input and output impedances, and overall quality. With opamps, the pass-band regions can also be amplified if necessary. Fig. 5 shows the active-rc (inductorless) implementation of a bandpass filter utilizing opamps. his circuit is actually a combined low-pass and high-pass filter to create a band-pass effect. Derive the expression for the transfer function H(j) for this filter then select the R and C values to meet the following specs: f L =.95kHz, f H =.5kHz midband gain of 3.5 volts/volt. n input impedance greater than kω over all frequencies. C2 R2 C R +5V v out -5V Figure 4 First order active-rc bandpass filter. 3

4 Lab : Introduction to Signals, ive RC Filters and Opamps Measure the magnitude of the filter at the lower and upper 3dB frequencies. Comment on any discrepancies you observe between the 3dB frequencies you designed for and your measurements? Comment on the difference between your bandpass filter and the ideal transfer function model in Fig. 4. What suggestions, if any, do you recommend for an improved frequency response? If time permits, modify your design as required. D. Notch Filter Design Like the band pass filter, the notch filter is simply the combination of a low pass filter and a high pass filter. However, in the case of the band pass filter, the frequencies of interest are passed by both the low pass filter and the high pass filter. his allows the two filters to be connected as shown in Fig. 4. his scheme will not work for a notch filter, since most of the frequencies attenuated by the low pass filter are in the pass band of the high pass filter, and vice versa. hus it is necessary to build a high pass filter and a low pass filter, and sum them using a summing amplifier. Design an active-rc notch filter to meet the following specs: 2 db of attenuation at khz, which is the most attenuated frequency pass band gain of 3.5 V/V n input impedance greater than kω over all frequencies. Measure the magnitude of the filter at the lower and upper 3dB frequencies. Comment on any discrepancies you observe between the 3dB frequencies you designed for and your measurements? Comment on the difference between your notch filter and the ideal transfer function model in Fig. 4. What suggestions, if any, do you recommend for an improved frequency response? If time permits, modify your design as required. E. bout Your Lab Report Your lab report should contain all of the lab results (data, graphs, drawings, etc.) It should be a self-contained self-explanatory report. It should be more than a list of answers to the questions in the lab notes. Your comments on the results should reflect your understanding of the lab exercises. Your well thought out reasoning and analyses of the experimental results will be appreciated and reflected in your grade. he report need not be typed or prepared with a word processor, however, points will be deducted for a sloppy, un-professional report. 4

5 Lab : Introduction to Signals, ive RC Filters and Opamps ppendix. Resistor Color Codes Resistors are identified by four color bands. he fourth band is always gold or silver and indicates the resistor precision. If we consider the other bands as displayed in Figure 4, the value of the resistor can be described as follows, [( B ) + B 2 ] B 3 hus, a resistor of colors Brown, Black, Red would have a value of, [( ) + ] 2 = = Ω Band Band 2 Band 3 Figure 4. Resistor color bands. Gold/Silver Color Value Black Brown Red 2 Orange 3 Yellow 4 Green 5 Blue 6 Violet 7 Grey 8 White 9 5

6 Lab : Introduction to Signals, ive RC Filters and Opamps.2 Measuring RMS values and mplitudes he RMS value of a periodic current/voltage signal is defined as a constant that is equal to the dc current/voltage that would deliver the same average power to a resistance, R. hus, P RI2 rms = = -- RI 2 () t dt I rms = -- I 2 () t dt V rms = -- V 2 ()t t d () (2) (3) he digital multimeter on your lab bench is reading in RMS units. You might want to compare this with the ac signals displayed on your oscilloscope for some sample signals from your signal generator. For the sinusoidal signals that you will be measuring most often, the peak value is related to the RMS value by: V p V rms = Parts List (2) LM74 Operational mplifiers Resistors Capacitors 6